DE3545374A1 - DETERMINATION CIRCUIT FOR NUMBER SCANNING - Google Patents

Description

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description

The present invention relates to a digit sampling determination circuit and a sampling digit determination method. Such a circuit or such a method is used in key input devices.

Fig. 4 shows the circuit diagram of a key input device, and Fig. 5 shows the by means of a flow chart Control sequence for the key input device shown in FIG.

According to FIG. 4, the device contains a key matrix 11 of the Key input device and a buffer 12 for determining or defining digit samples of the key matrix 11- The buffer has an OR element for each digit

13. Each of the OR gates 13 is common and simultaneous a determination signal C is supplied. In addition, 13 signals from Address registers BL entered. As FIG. 4 shows, the search for the actuated key is carried out by means of scanning signals D1 .... D7 as well as input signals KL1 .... KL4.

The digit scans take place according to the sequence outlined in FIG. At the beginning, all digit scans are controlled by C = 1. If KL = 0, this means that no key has been pressed. If KL Φ 0, this means that a certain key has been pressed. Address registers BLO .... BL6 are then activated. If KL Φ 0, the values for BL and KL are stored and the key operation search process is ended.

In the method described above, the key search is carried out by turning on all the scanning signals. Will a key input is detected, the scans are initiated one after the other until the pressed key is identified. The example shown is a Two to eight scanning determinations are necessary, depending on the position of the key being pressed. Of the Key recognition period from when a key was pressed to when it was saved of the key data, i.e. up to the point in time at which the key input is effectively accepted, fluctuates in Dependency of the key position. Therefore, the key recognition period is relatively long.

In view of the problems set out above, the invention is based on the object of an improved scanning key determination method and to provide a determination circuit whereby key fluctuations are detected as well as the mean processing time is shortened.

This object is achieved by the invention specified in the patent claims.

In the determination circuit according to the invention the individual scanning lines are not activated one after the other from the first to the last line, but rather it is initially carried out with the aid of the group scanning signal supply device a preselection in which a group of scan lines is determined within the that scan line is located which corresponds to the pressed key. After determining this group signals are then fed to the individual scanning lines within the group in order to determine the scanning line in question to be specified within the previously selected group. This reduces the time for the

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Scans. In addition, the fluctuations are reduced the processing time for different scan lines. The mean time to find an actuated Button decreases.

The following are exemplary embodiments of the invention explained in more detail with reference to the drawing. Show it:

1 is a circuit diagram of an essential part of a key input device according to the invention,

FIG. 2 is a flow chart for explaining the operation of the key input device of FIG. 1;

Fig. 3 is a block diagram of an example of a

integrated circuit in connection with the present invention,

Fig. 4 is a circuit diagram of the essential part of a key input device, and

FIG. 5 is a flow chart of the key input device shown in FIG.

In the present example, the invention is applied to a method for key search with the aid of Digit scan determination signals from an integrated Circuit can be output to an external circuit. Fig. 1 shows the relationship between a Buffer and a key matrix, FIG. 2 the associated flowchart, and FIG. 3 the block diagram of a integrated circuit.

The invention can also be used in methods other than key search methods.

'β'

According to FIG. 3, a read-only memory (ROM) is used to store program commands, and a command decoder is used for decoding Commands, and the parts PU and PL are command counters for the ROM. SU, SL, RU and RL are stack register memories (stacks) for subroutines, RAM is a read / write memory, BM and BL are address registers for the RAM, DEC is a decoder for decoding the contents of the address register, and BUF is an output buffer, via the scanning signals are output in accordance with the content of the address register. Acc is an accumulator. A carry flag for a buffer over which the sample signal is output according to the arithmetic operation of the accumulator or accordingly a program command to set a carry. KH and KL are input buffers. The buffer KL is used as a Input terminal used for key data.

According to FIG. 1, an input device has a key matrix 1 ^un <3, an output buffer BUF, which is shown in FIG. 3, and via which scanning signals DO ... DI2 are output. The scan lines in the buffer 2 are divided into three groups: the first group GI corresponds to the RAM address signal BL = 13; the second group G2 corresponds to BL = 14, and the third group G3 corresponds to BL = 15. The signal BL = 13 is given as group scanning signals via the OR gates of the scanning lines of the group G1, the signal BL = 14 to the scanning lines in the group G2 is given and the signal BL = 15 is given to the scan lines in group G3. In addition, signals BL = = .... BL = 11 are applied as individual scanning signals to one scanning line in each case.

The circuit according to the invention operates in the following described manner, reference being made to the flow chart shown in FIG. Here assumes that a key is at the intersection

was operated by D5 and KLI, as it is in the key matrix 1 is indicated by a circle.

First, the scanning lines of the key group G1 are simultaneously determined by BL = ■ 13, so that scanning signals D1... D3 are fed to the key matrix. Because KL = 0 and BL Φ 15, BL is increased by "1" (BL = BL + 1) and takes the value "14" (BL = 14).

After the three scan lines of group G1 have been processed simultaneously, scan lines D4 ... D6 are next determined simultaneously. Because of KL Φ 0, the program branches to the right in FIG. 2 and asks whether BL = 13. Since the answer is "No", a further inquiry is made as to whether BL = 14. This time the answer is "Yes", and the program branches further to the right in FIG. The scan lines in the second group G1 is determined, starting with BL = 3. In this example applies KL Φ 0 if BL = 4. The values of BL and KL are stored in KL Φ 0, and thus the key scan is complete.

In this example, the key search is performed at Use of the same number of scanning signals (D1 ... D7) and input signals (KL1 ... KL4) as for the example of Fig. 4. In the present case, there are seven scan lines in two groups of three each Lines and a third group with only one scan line divided. Thus, in the invention between two and five determinations of scans necessary, in contrast to two to eight scans

Moods in the example explained above according to FIGS. 4 and 5. In other words: the difference between The maximum and minimum number of determinations is reduced from six in the example explained at the beginning to three in the present invention. This results in a minimization of the time fluctuations

when searching for keys, also a reduction in the average number of determinations from 5 to 3.57. the the mean time for a key search is therefore reduced. 5

As is apparent from the above description, in the invention, the scanning lines are in plural groups and a group scan signal is applied to all scan lines of the first group at the same time given. This is then also done, if necessary, for the second and third groups. Then be on the scan lines of a particular (selected) group are given individual scan signals. In comparison to the example explained at the beginning, in which scanning signals are successively applied to all scanning lines the fluctuations in processing time are reduced, as is the mean processing time. In addition, circuit efficiency increases while processing speed increases improved.

The number of groups of scanning lines is not - as in the above embodiment - three, instead, different numbers of groups and scanning lines can be provided within the individual groups be.

Claims (2)

KlI NkKKSCIIMm '-NILKOVIIIKSCM \ PKTENTA ₁ NWUTE ί \ K 30 255/6 SHARP KABUSHIKI KAISHA Osaka, Japan Dec. 20, 1985 Priority: Dec 28, 1984 - No. 59-275218 JAPAN Determination circuit for digit scanning Claims Jl). Determination circuit for the digit scanning, for example ^, as a digit key matrix, / marked by "? a plurality of groups (G1-G3) of scanning lines (D1-D7), a group scanning signal supply device (2, BL13-BL15), with which in at least one group (e.g. G1) of scanning lines (D1-D3) a group scanning signal simultaneously is applied to these scanning lines (D1-D3), and a single line scanning signal supply means (BL0-BL6), the single scanning signals in different Points in time to the scanning lines (e.g. -D1-D3) from the group scanning signal supply device (2, BL13-BL15) selected group (e.g. G1). 2. Sampling digit determination method, characterized by
following steps: ι ♦ 3 · - dividing the scanning lines into several groups of scanning lines, - Supplying a group scanning signal to all 5 scanning lines in at least one of the groups of scan lines, and Supplying individual scanning signals to the scanning lines in a special one of the group scanning signal selected group to differ- 10 borrowed times.